Extraction device of glass containers for pharmaceutical and/or cosmetic use and extraction pincer

ABSTRACT

A device for extracting glass containers for pharmaceutical and/or cosmetic use from trays that have recesses or impressions housing glass containers or the like arranged consecutively includes a wheel sector or star segment, which is caused to rotate around a horizontal axis in a circular path and which is brought above a tray moved forward at the same peripheral speed as the wheel sector or star segment. An outer peripheral surface of the wheel sector or star segment is formed as an arc of circumference and carries extraction pincers of the single glass container arranged between each other at a first reciprocal distance equal to that between the recesses or impressions of the tray, each of said extraction pincers having a pair of yielding arms that house a single glass container.

The present invention relates to an extraction device of glasscontainers for pharmaceutical and/or cosmetic use from trays and anextraction pincer.

In the field of the handling of glass containers for pharmaceuticaland/or cosmetic use, such as syringes, cartridges and the like, specificarrangements of parts and/or machines are used which determine therequired handling.

It should also be taken into account, for example, that the termsyringes actually indicates syringe bodies, comprising the final flangedpart and the cylindrical body containing the treatment liquid with itstip on which the needle is generally inserted.

The transporting and storage of the glass containers defined above suchas glass syringes is effected with the aid of trays made ofthermoplastic material (plastic tray), equipped with negativeimpressions of the body (diameter) of the syringes according to thetheir diameter.

These trays are widely used for both the shipment of syringes from theglass-tube transformer to the customer (pharmaceutical industry whichsubsequently provides for the washing, sterilization, assembly andfilling) and also within the manufacturer's production site fortransferring the syringes from one processing step to the next.

The trays are therefore used in machines where the transfer of syringesor similar objects may be required from a machine area that transportsthem according to a certain frequency or a certain step arrangement, forexample on trays, towards a machine area that transports them in aspaced and continuous manner consecutively, such as a conveyor.

Solutions are known for example in which the syringes are extracted froma tray in which they are contained and arranged in different ways. Ithas been noted that the limitation of these solutions is that theydamage or rub the syringe on the container itself or the extractionmethod ruins the thermoplastic tray.

Some solutions, in fact, intervene on the syringes through a plastic“hook” that “detaches” them from the container or tray and the syringes,rubbing against the plastic, are consequently damaged. In particular,the syringes are stained by the plastic itself.

In other solutions, a robot or a gripping device is used which withdrawsthe syringes from the container or tray. In this case, in order toprevent the syringes from rubbing against the plastic of the container(tray), the slots or grips of the container are “opened” with special“scissors”. By doing so, the syringe containers are damaged.Furthermore, the device for opening/closing the slots requires numerousmaintenance interventions, which are extremely expensive as they arehigh precision.

As part of the various and different handling processes, the syringesare loaded into the trays and subsequently extracted to be conveyed toan automatic unit positioned downstream. There are machines or groups,for example, in which the syringes are extracted from theabove-mentioned trays and conveyed to a subsequent washing machine, etc.

A technical problem that creates difficulties in these machines orgroups arises when the syringes, which are arranged in the trays at apredetermined distance based on the negative impressions of thesyringes, must be transferred to a conveyor or similar equipment inwhich the distance between the syringes is different. Another problemthat arises is that of having the feeding of the trays according to afirst spatial direction and providing for the subsequent movement of thesyringes withdrawn according to a different spatial direction. What isdescribed above is not easy to overcome with the machines currentlyavailable.

EP 2441711 relates to a method for extracting glass containers accordingto the preamble of claim 1.

WO 2007/121930 relates to a device for packaging articles which usesgripping elements on a rotating head.

The general objective of the present invention is to provide a sectorfor extracting glass containers for pharmaceutical and/or cosmetic usefrom trays and an extraction pincer capable of solving theabove-mentioned drawbacks of the prior art in an extremely simple way,economical and particularly functional manner.

A further objective of the present invention is to provide a device forextracting glass containers for pharmaceutical and/or cosmetic use fromtrays and an extraction pincer which avoids any possible indentation orscratching in general of the syringe being handled.

Another objective of the present invention is to provide a device forextracting glass containers for pharmaceutical and/or cosmetic use fromtrays and an extraction pincer which guarantees continuity in theextraction of the containers from trays.

The above objectives are achieved by a device for extracting glasscontainers for pharmaceutical and/or cosmetic use from trays and anextraction pincer produced according to independent claim 1 and thefollowing subordinate claims.

The structural and functional characteristics of the present inventionand its advantages with respect to the known art will become even moreevident from the following description, referring to the attachedschematic drawings, which show an embodiment example of the invention.In the drawings:

FIG. 1 shows an overall perspective view of a part of a syringetreatment machine in which a handling system is provided for extractingsyringes from a tray and transferring them to a continuous conveyoraccording to the present invention, positioned and operating in a firstoperating position of the system with the robot head for withdrawal;

FIG. 2 is a perspective view, similar to that of FIG. 1 , in a secondoperating position with the robot head releasing the syringes onto alinear conveyor;

FIGS. 3 and 4 show a partial perspective view and a sectional view ofthe system which allows the rotation according to a circumference ofwheel or star sectors of a device for extracting syringes fromunderlying trays;

FIGS. 5 and 6 show perspective views of one of the wheel or star sectorsequipped with extraction pincers;

FIGS. 7 and 8 show a section taken along the line VII-VII of FIG. 6 andan enlarged detail according to the circle B indicated in FIG. 6 ofparts of the wheel or star sector;

FIGS. 9 and 10 show perspective views of a robot head, as illustrated,with gripping elements as positioned in FIGS. 1 and 2 , respectively;

FIGS. 11 and 11 b show split sectional perspective views and through anenlarged detail according to the circle C of the robot head as shown inFIGS. 1 and 9 in the withdrawal position;

FIGS. 12 and 12 b show split sectional perspective views and through anenlarged detail according to the circle D of the robot head as shown inFIGS. 2 and 10 in the release position;

FIGS. 13 and 13 b show perspective views similar to those of FIGS. 11and 11 b according to different sections and details according to thecircle E in the withdrawal position;

FIGS. 14 and 14 b show perspective views similar to those of FIGS. 12and 12 b according to different sections and details according to thecircle G in the release position;

FIGS. 15, 16 and 17 show, in three different positions, the movementsequence of the three wheel sectors or star segment during theextraction of the syringes;

the schematic figures from 18 to 23 show a series of positions suitablefor understanding how a single sector moves in its circular path aroundthe axis X.

With reference to the exemplary and non-limiting figures, these show anembodiment of a device for extracting glass containers forpharmaceutical and/or cosmetic use, such as syringes, from trays and arespective extraction pincer from a tray.

Indications such as “vertical” and “horizontal”, “upper” and “lower” (inthe absence of other indications) should be read with reference to theassembly (or operating) conditions and referring to the normalterminology used in current language, where “vertical” indicates adirection substantially parallel to that of the force of gravity vector“g” and a horizontal direction perpendicular to it.

Referring first to FIGS. 1 and 2 , a syringe handling system provides afeeding of trays 11, for example of the type generally used in thesemachines, each containing a row of syringes 12 or the like, housed insuitable recesses or impressions 13 of the same trays 11. The trays 11are caused to move and advance at a predetermined distance from eachother on a horizontal feeding plane 14 according to a loop pathindicated by the track 15, in steps and/or continuously depending on thespecific operating phase.

The trays 11 are thus brought and passed under an extraction device ofthe syringes 12 from the trays 11. The extraction device comprises threewheel sectors 16, 17 and 18, or star segments, caused to rotate around acommon horizontal axis X along a circular path through respective motors19, 20 and 21. The wheel sectors 16, 17 and 18 on an outer peripheralsurface formed as an arc of circumference, inserted in a suitable archedgroove 22, carry a series of extraction pincers 23 of the single syringe12 arranged at a first reciprocal distance k corresponding to the pitchbetween consecutive recesses or impressions 13 of the trays 11.

As clearly shown in the figures, the single wheel sector 16, 17 and 18,rotating around the axis X, moves on a vertical plane, perpendicular tothe feeding plane of the trays, and follows a trajectory, indicated bythe arrow F, which is in a tangent direction to the feeding plane 14,and to the trays 11, according to a circular pattern. The three wheelsectors 16, 17 and 18 therefore occupy less than three quarters of thecircumference they are moving along and can thus follow each other inthe above-mentioned trajectory as will be seen hereunder.

Their movement is such as to allow the extraction of the single syringe12 from the single tray 11 moving on the lower horizontal feeding plane14 (FIG. 1 ). Furthermore, it is such as to guarantee their movementtowards an upper position, in particular a gripping position of a head24 of a manipulator or withdrawal robot 25. All of this takes placethanks to the synchronism between the wheel sectors 16, 17 and 18 forthe extraction of the syringes 12 and the movement of the tray 11 whichis part of the flow of the trays on the horizontal plane.

The head 24 of the withdrawal robot 25 provides a series of grippingelements 26 that are movable and variable in position with respect toeach other according to the choice of the pitch or distance betweenconsecutive gripping syringes 12. The robot 25, in the movement of itshead 24 in space towards a continuous linear conveyor 27 below (FIG. 2), is capable of varying the pitch or distance between consecutivegripped syringes 12 for preparing them to be arranged in housings 48provided in said linear conveyor 27.

It should be noted that these housings 48 of the linear conveyor 27, forexample a belt, are arranged at a second distance h different from thefirst distance k so that the syringes are released at a reciprocaldistance different from the distance they had when they were carried bythe wheel sectors or star segments 16, 17 and 18 i.e. from the trays 11.And this second distance h turns out to be specifically the correctdistance for deposition on the linear conveyor 27.

In this way, the head 24 of the robot 25 effects a linear deposit on theconveyor 27 with a different deposition pitch as required and accordingto the type of conveyor 27 in use.

An important detail of the present invention, which solves the problemsof the known art, is that of obtaining a variation in pitch between theindividual syringes through this movement from the trays to the linearconveyor. The system or the robot head in fact allows the syringes to betaken at one pitch and deposited on a subsequent conveyor or machinestation at a different pitch.

Specifically, the syringes 12 are extracted from the single tray 11arranged at a first distance k between one syringe and another (FIG. 1). This extraction takes place through the wheel or star sectors 16, 17and 18 with a series of extraction pincers 23 which extract the singlesyringe 12 with an identical pitch. The wheel or star sectors 16, 17 and18 then cause the syringes 12 to be withdrawn from the head 24 of therobot 25.

Through this transfer, therefore, the required spacing between theindividual syringes 12 takes place and also a variation in theirpositioning on the planes or in the desired parts of the machine, usefulfor their correct treatment. By means of the present invention, in fact,the syringes fed on the trays according to a first spatial direction aremoved so as to acquire a different spatial direction.

FIGS. 3 to 8 show some aspects of the extraction device, the compositionof the single wheel or star sector 16, 17 and 18 and the rotationmovement of these sectors according to a circumference.

The extraction device, as already mentioned, comprises three wheelsectors 16, 17 and 18, or star segments, caused to rotate around acommon horizontal axis X by means of respective motors 19, 20 and 21.The wheel sectors 16, 17 and 18 on an outer peripheral surface, insertedin a suitable arched groove 22, carry a series of pincers 23 forextracting the single syringe 12.

As clearly shown in the figures, the single wheel sector 16, 17 and 18,rotating around the axis X, moves on a vertical plane and follows acircular trajectory, indicated by the arrow F (FIG. 3 ), which proves tobe in a direction tangent to the feeding plane 14 and, therefore, to thetrays 11. The three wheel sectors 16, 17 and 18 occupy less than threequarters of the circumference they are moving along and can thus followeach other in the above-mentioned trajectory.

Each single wheel sector 16, 17 and 18 or star segment comprises a bodyin two halves 50, 51 on whose peripheral surface having a largerdiameter facing outwardly, facing recesses are formed in each of saidtwo halves 50, 51, which define the previously mentioned arched groove22.

The series of extraction pincers 23 of the single syringe 12 (FIGS. 5 to8 ), as already mentioned, arranged at a first distance k from eachother, is inserted in this groove 22.

These pincers or jaws 23 are made of plastic material and have a body 52constrained to one of said sectors and from which two side arms 53, 54extend, yielding to form an elongated U. The first arm 53, slightlycurved in a recess or curved portion 49 towards the free end for housingthe syringe 12, has a substantially constant thickness. The second arm54 is provided with an intermediate tooth 55 protruding inwardly andfacing the other arm 53. This tooth 55 forms a supporting surface forthe syringe 12 which it houses in a curved portion 49 mirroring that 49provided on the first arm 53.

The single extraction pincer 23 is in fact brought from the sector 16(as shown in FIGS. 1 and 15 ) or 17 or 18 to become tangentially engagedon the syringes 12 according to the arrow F and allows the syringe 12 tobe accommodated inside the two arms 53, 54.

More specifically, the syringe 12 is arranged within the curved portions49 of the arms 53 and 54, with the arm 54 advancing first with respectto the arm 53. This causes the syringe 12, when it becomes engagedbetween the arms 53, 54, to become abutted against the notch 55 of thearm 54. This positioning causes the syringe 12 to be extracted from theimpression 13 of the tray 11 without any effort, gently, without anyrubbing or friction.

The sector in extracting action brings one pincer after another toextract a respective syringe 12 without any effort.

Holes 56′ are provided in the body 52, which receive fastening pins 56to the respective sector within one of the two halves 50, 51 of the bodyof the wheel sector 16, 17 and 18 or star segment.

Each wheel sector 16, 17 and 18 or star segment is caused to rotatearound the axis X as it is carried by a respective arm 57, 57′, 57″connected to a respective section of shaft 58, 58′, 58″. These sectionsof shaft 58, 58′, 58″ are arranged coaxially with respect to each otherand are driven by motors 19, 20 and 21 through transmission belts 59,59′, 59″. The motors 19, 20 and 21 are determined in particularmovements in the electronic cam so that the wheel sectors 16, 17 and 18or star segment follow each other with speed variations and stoppagesindependently of each other, so as to ensure a continuous and constantsupply of sectors full of syringes beneath the head 24 of the withdrawalrobot 25.

With respect to FIGS. 9 to 14 b, these show the robot head and itsfunctionality in an exemplary and non-limiting embodiment, in greaterdetail.

The head 24 of the withdrawal robot 25 provides a series of grippingelements 26 which are movable and variable in position with respect toeach other according to the choice of the pitch or distance betweenconsecutive syringes 12, both in the gripping position and in thedeposition or release.

The head 24 comprises an external box in two coupled parts 30, 31 whichis arranged vertically with a lower elongated opening 32 formed halfwayon each of the two parts 30, 31. The gripping elements 26 protrude fromsaid opening 32 and are in the form of a series of rods 33 provided attheir free ends, with gripping elements (FIGS. 11-14 ). In the exampleshown, each gripping element consists of a sucker 34, but a pincer orother similar gripping element could be identically provided.

The head contains a movement and position-variation mechanism of thegripping elements 26, with respect to each other, which is describedhereunder in its exemplary but non-limiting embodiment.

The rods 33 are arranged at their other end, and each rod extends fromfirst free ends of tubular bodies 35. At second ends, the tubular bodiesare integral with links 36, arranged in the form of a chain articulatedconsecutively by means of intermediate biscuits 37 hinged to the same(FIGS. 13-14 b). The single links 36 have shaped side surfaces 38collaborating with each other so that subsequent links 36 can move on aplane while remaining in contact with each other.

It should also be noted that there are twelve links 36 in the examplecarrying twelve tubular bodies 35, twelve rods 33 with respectivesuckers 34, but they could be in another preselected number.

One link 36′, intermediate between the other links 36, is free to rotatearound pins 38 (FIG. 13 ), which are hinged on plates 39. These plates39 are arranged integrally inside the two coupled parts 30, 31 of thebox.

Final end links 36″ of the series of links 36 also carry pins 40 (FIGS.11 and 13 ) that are engaged in arched slots 41 formed at opposite endsof the plates 39. These pins 40 are in turn connected and arranged freeto rotate in end openings 42, the latter formed at a first end of squarerods 43. Said square rods 43 are in turn centrally hinged in a pin 44integral with the plates 39 around which they oscillate. Opposite endsof these square rods 43 are connected by means of pins 45 to ends ofstems 46 of actuation cylinders 47 articulatedly connected at their freeend to the plates 39. The actuation of the cylinders 47 causes anoscillation of the square rods 43 with a variation in the position ofthe series of links 36 and therefore of the gripping elements 26. Thanksto the presence of the arched slots 41, in fact, the links 36 acquiretwo different extreme operating positions. In a position close to eachother (FIGS. 13 and 13 b) the links 36 are arranged in an arc and withgripping elements 26 which are arranged almost converging towards acentral point. Supporting surfaces 60 obtained in consecutive links 36in the upper part of the same are detached in this position.Furthermore, facing supporting surfaces 61 are provided on the tubularbodies 35, which are arranged in contact with each other to favour theconvergent position of the gripping elements 26.

In a second position, aligned along a straight line (FIGS. 14 and 14 b),the links 36 are shifted so that the gripping elements 26 are allparallel to each other and spaced apart. The above-mentioned supportingsurfaces 60 in this position are caused to be arranged in support andfavour the aligned and parallel position of the gripping elements 26.

The first position, with rods close together and converging at onepoint, corresponds to the withdrawal position of the syringes 12 fromthe wheel sectors 16, 17 and 18, or star segments, when brought into thewithdrawal position with syringes arranged according to theabove-mentioned first distance k. The second position, on the otherhand, with parallel rods, corresponds to the release position of thesyringes 12 on the linear conveyor 27 carried by the head 24 of therobot 25.

In this second position, a second distance h is obtained betweensuccessive syringes, different from the first distance k they had whenthey were carried by said wheel sectors or star segments or by the trays11, the second distance h being exactly the correct distance fordeposition in the linear conveyor 27.

In this way, it can be seen how the robot 25 in moving its head 24 inspace towards an underlying linear conveyor 27 is capable of varying thepitch or distance between successive gripped syringes 12 by suitablyactivating the cylinders 47 between the two above-mentioned positions.In this way, the head 24 of the robot 25, on the one hand, effects acorrect withdrawal from the sectors 16, 17 or 18 thanks to the correctposition also determined by the supporting surfaces 61 of the tubularbodies 35 and, on the other hand, a linear deposition on the conveyor 27with the deposition pitch always correct determined by the supportingsurfaces 60 of the links 36.

If syringes 12 having different diameters, taken from sectors withdifferent pincers 23 in trays with impressions having a different pitch,are to be treated and deposited correctly on the linear conveyor, therods 33 of the gripping elements 26 must be replaced with rods having avariable length.

Thanks to the particular head 24 of the robot 25 described above, theuser can even intervene by defining a preselected and defined number ofsyringes.

This can be particularly useful and advantageous if the format of thesyringe varies, and the type of tray and its number of internalimpressions are also correspondingly variable.

This is effected using a particular algorithm that allows thespeed/positioning of the star sectors to be varied so that they can“move”, distributing the syringes step by step and continuously (withoutholes). All of this takes place even if the number of syringes insidethe tray has changed according to the size of the syringe/composition ofthe tray.

This is also thanks to the fact that the robot head is capable of takingthe syringes at a certain pitch (distance between one syringe and theother) from the star sector and releasing these syringes to a subsequentprocess station at a different pitch (distance between one syringe andthe other).

The three FIGS. 15, 16 and 17 show the movement sequence of a wheelsector 16, 17 and 18 or star segment when it acts on a tray which ismoved and advanced at a predetermined distance from a previous tray andfrom a subsequent tray on the horizontal feeding plane 14.

The first FIG. 15 shows how the sector, for example 16, carries theseries of extraction pincers 23 in correspondence with the initial partof the tray 11 carrying a predetermined number of syringes 12.

The first of these extraction pincers 23 becomes engaged on the firstsyringe 12, present in a first recess or impression 13 of the tray 11,and removes it, carrying it with it. The same operation is effected bythe subsequent pincers 23 which act on the subsequent syringes 12,arranged in the subsequent impressions 13 which are provided in the tray11.

The second FIG. 16 shows how the sector 16, continuing in its rotation,already has the respective syringes 12 in a certain number of extractionpincers 23 and how the tray 11 is simultaneously moved forward insynchronism on the horizontal feeding plane 14.

Finally, the third FIG. 17 shows how the sector 16 has withdrawn severalsyringes 12 and the tray 11, which is moving forward in perfectsynchronism, has most of the impressions 13 empty. The sector 16 hastherefore almost completed the extraction of the syringes 12 from thetray 11.

The wheel sector or star segment 16 in this example, thanks to theparticular design and conception of the extraction pincers 23 present init, gently extracts the single syringe 12 from the tray 11, avoiding anypossible friction or staining between the parts in question.

The present invention, in fact, allows the wheel sector or star segment16 to “engage with” the syringes 12 tangentially and one by one insuccession, by means of a gentle extraction and without “forcing” theextraction of the single syringe 12. This is thanks to the arrangementof the parts and to the fact that the single pincer or jaw 23 isproduced with the two side arms 53, 54 yielding. More specifically, anarm 53 in its curved portion 49 accommodates the syringe 12 which isalso accommodated in the facing curved portion 49 of the other arm 54.This second arm 54 is provided with an intermediate notch 55 protrudinginwardly which collaborates for receiving the syringe 12 with ease andwithout any effort.

This arrangement of parts ensures a perfect and constant synchronism ofthe wheel sector 16, 17 or 18 for the extraction of the syringes 12 withthe continuous movement of the tray 11 in perfect synchronism at thesame advancement rate.

Each wheel sector or star segment, 16, 17 or 18 is in fact caused torotate around the common horizontal axis X according to a circular pathand when it is brought above a tray from which the containers orsyringes are to be extracted, each tray is moved forward at the sameperipheral speed as the sector acting in extraction.

The three figures mentioned above also show how their movement iseffected in this rotary motion around the axis X when extractingsyringes or similar containers 12.

The wheel sectors 16, 17 and 18 or star segment are in fact determinedin particular movements in the electronic cam so that they follow eachother in such a way as to ensure a continuous and constant supply ofsectors full of syringes 12 to the above head 24 of the withdrawal robot25, which in this way has a constant and continuous supply of syringes12.

In practice, the sectors 16, 17 and 18 have accelerations anddecelerations which are such that the single sector, for example thesector 16 in FIG. 15 , when brought above the single tray 11, iscontrolled at the same peripheral speed and follows it until the tray 11is completely emptied due to the various positions acquired between theparts, some of which are shown in FIGS. 15 to 17 .

At the end of the extraction of the syringes 12 (FIG. 17 ), the sectorthen accelerates and moves to the end of the previous sector which hadalready been filled with syringes (see for example the sector 17 whichgoes to the end of the sector 18 in FIG. 15 ).

The single sector, for example the sector 18 in FIG. 1 , which on theother hand must face the head 24 of the robot 25 to allow the withdrawalof the syringes, moves to the withdrawal position and stops them tospecifically allow the withdrawal of the syringes 12.

The sector, for example the sector 18 in FIG. 17 , once emptied, is thenrapidly prepared for facing a new tray 11 full of syringes, which justas rapidly becomes synchronized with the sector 18 on arrival. All ofthis is then moved forward at the same speed when the extraction of thesyringes 12 from the tray is initiated by the sector equipped withextraction pincers 23 of the single syringe 12.

This alternation between accelerations, advancing at a constant speed,accelerations, stoppages, etc. is indicated as an “electronic cam”controlled exclusively by a program and by the speed variations of themotors 19, 20 and 21 which synthesize a certain law of motion.

The schematic figures from 18 to 23 show how a sector moves in itscircular path around the axis X.

FIGS. 18, 19, 20 repeat the movement of the single sector in itsextraction phase, i.e. when, with the peripheral speed equal to that ofthe advancement of the tray 11, it extracts the syringes from the trayitself. The sector shown for example is sector 16.

At the end of this extraction phase, the sector 16 rapidly acceleratesto the position of FIG. 21 immediately behind the preceding sector 17.In this position both the sector 17 and the sector 16 stop. In this stopposition of the sectors 16, 17 a predetermined number of syringes iswithdrawn, partly from the sector 17 together with some initial syringescarried by the sector 16 thus moved. This withdrawal is indicated with90 in FIG. 19 from the sectors 16 and 17, and also with 90 in FIG. 20from the sector 17 and with 90 in FIG. 21 from the sectors 16 and 17.

FIG. 22 shows a subsequent position in which the emptied sector 17 hasrapidly moved until it is over a new tray to extract new syringes. Thesector 16, on the other hand, which has advanced in rotation for acertain length, stops and together with the sector 18, presents itselffor extraction. All of this naturally occurs in sectors 16, 18stationary in the withdrawal position, wherein the withdrawal isindicated with 90 as in the previous cases.

Finally, FIG. 23 shows how the sector 16, also emptied, starts its rapidrotation to move onto a subsequent tray whereas the sector 17 iscontinuing its extraction from the tray and the sector 18 is stationaryto allow the withdrawal of the predetermined number 90 of 12 syringesmentioned above.

It should also be noted that the invention proposes a new method.

This is in fact a method for the extraction of syringes contained in atray 11 and their transfer to a continuous conveyor 27. As can be seen,the trays 11 are provided with a series of recesses or impressions 13which house a series of syringes 12 or the like and are caused to moveforward and advance at a predetermined distance from each other on afeeding surface 14 in steps and/or continuously. In this way, the traysare brought beneath a device for extracting the syringes from the trays,wherein the extraction device comprises the wheel sectors or starsegments, 16, 17 and 18, caused to rotate around a common horizontalaxis X according to a circular path.

The wheel sectors or star segments 16, 17 and 18 have on an outerperipheral surface formed as an arc of circumference, a series ofextraction pincers 23 of the single syringe 12 arranged between eachother at a first reciprocal distance k. This distance k is equal to thedistance between recesses or impressions 13 of trays 11.

Furthermore, a robot head intervenes in the method which is providedwith movement in space and which provides a series of gripping elements26 for withdrawing said syringes 12 carried by the sectors and releasingthem onto the linear conveyor. The method of the invention provides fora series of innovative steps.

A step is in fact provided for extracting said syringes one at a timefrom said trays by means of said pincers carried by said sectors,wherein said sectors are caused to rotate tangent to said trays whichmove forward in synchronism with the rotation of the sectors.

This extraction has been found to be without any friction and such as tonot damage the syringes.

This step is followed by a step for withdrawing all of the syringestogether carried by said pincers of a single sector by means of saidwithdrawal elements of said robot head, once the rotation of said singlesector has been stopped.

Once the syringes have been withdrawn, this is followed by a step fortransferring all of said syringes withdrawn by said robot head from saidsectors to a position above said linear conveyor to arrange them in thehousings 48 of the conveyor 27.

To do this, an intermediate and completely innovative step must beimplemented. This step, which is effected during the transfer of saidrobot head, causes the syringes carried by the withdrawal elementspositioned at a first distance k to be moved to a second distance h,different from the first distance k, for depositing all the syringestogether on said linear conveyor 27 in the relative housings 48.

For this purpose, the gripping elements 26 are movable and variable inposition with respect to each other.

Finally, there is naturally a step for releasing all of the syringesbrought together at the second distance k on the continuous linearconveyor.

As seen and written, the examples refer to syringes, but the method andthe system in its parts are identically suitable for glass containers asspecified above.

Further variants are possible from the embodiments described above,without departing from the teaching of the present invention.

Finally, it is evident that groups and methods thus conceived canundergo numerous modifications and variations, all of which are withinthe scope of the invention; furthermore, all the details can be replacedby technically equivalent elements. In practice, the materials used, asalso the dimensions, can vary according to the technical requirements.

The objective mentioned in the preamble of the description has thus beenachieved.

The protection scope of the present invention is defined by the enclosedclaims.

The invention claimed is:
 1. A device configured for extracting glasscontainers for pharmaceutical and/or cosmetic use from trays, whereinthe trays (11) are provided with a series of recesses or impressions(13) which house a series of the glass containers (12) arrangedconsecutively, the device comprising: at least one wheel sector or starsegment, (16,17 and 18) which is caused to rotate around a horizontalaxis (X) according to a circular path and which is brought above a traywhich is moved forwards at a same peripheral speed as the wheel sectoror star segment, wherein said at least one wheel sector or star segment(16,17 and 18) carries, on an outer peripheral surface formed as an arcof circumference, a series of extraction pincers (23) of a single glasscontainer (12) arranged at a first reciprocal distance (k) from oneanother that is equal to a distance between said recesses or impressions(13) of the tray, wherein each of said extraction pincers (23) has apair of yielding arms (53,54) configured to house a single glasscontainer (12), wherein said at least one wheel sector or star segment(16, 17 and 18) comprises a body having two halves (50,51), and wherein,in a peripheral surface of the body having a larger diameter and facingoutwardly, facing recesses are formed in each of said two halves (50,51), said facing recesses defining an arched groove (22), which receivessaid series of extraction pincers (23).
 2. The device according to claim1, wherein said extraction pincers (23) are made of a plastic material.3. The device according to claim 1, wherein said extraction pincers (23)have a body (52), integral with said at least one wheel sector or starsegment (16,17 and 18), two side yielding arms extending (53,54) fromsaid body of said extraction pincers and forming an elongated U.
 4. Thedevice according to claim 3, wherein both of said yielding arms (53,54)have a curved portion (49) towards a free end of said yielding arms,said free end facing an opposite arm (54,53).
 5. The device according toclaim 3, wherein one (54) of said two arms (53,54) is provided with anintermediate tooth (55), protruding inwardly, facing another one of saidtwo arms (53), said intermediate tooth forming a supporting surface forthe single glass container (12).
 6. A method of extracting glasscontainers for pharmaceutical and/or cosmetic use from trays with adevice according to claim 5, wherein the trays (11) are provided withthe series of recesses or impressions (13) which house the series ofglass containers (12), arranged consecutively, comprising: causing theat least one wheel sector or star segment (16, 17 and 18) to rotatearound the horizontal axis (X) along the circular path; and bringing theat least one wheel sector or star segment (16, 17 and 18) above one ofsaid trays (11), which is moved forward at the same peripheral speed assaid at least one wheel sector or star segment; bringing each of thepincers (23) by the at least one sector (16,17 or 18) to engage on thesingle glass container (12) arranged in the tray according to a pathtangential to the tray, wherein in the step of bringing, said at leastone wheel sector or star segment is brought above said single tray,which is moved forward at the same peripheral speed as the at least onewheel sector or star segment; and advancing a second arm (54) of saidtwo arms first with respect to a first arm (53) of said two arms, sothat the single container (12), when engaging between the two arms(53,54) becomes abutted against a notch (55) of the second arm (54) andis extracted from the tray by the pincers (23 wherein a device forextracting the glass containers from the trays is used, which comprisesthree wheel sectors or star segments (16,17 and 18) which areindividually driven by a respective motor (19,20,21) which causes saidthree wheel sectors or star segments (16,17 and 18) to rotate around thehorizontal axis (X) according to the circular path, and wherein saidthree wheel sectors or star segments, (16,17 and 18) follow each otherwith speed variations and independent stoppages of one sector withrespect to other sectors so as to ensure a continuous and constantsupply of sectors (16,17 or 18) full of the glass containers (12) belowa head (24) of a robot (25) for withdrawing a predetermined number ofthe glass containers all at once.
 7. An extraction pincer for a singleglass container from a tray to be used in a device according to claim 1,wherein said extraction pincer is made of a plastic material, andwherein said extraction pincer comprises the body (52) from which thetwo side yielding arms (53,54) extend, to form the elongated U, andwherein the first arm (53) has a curved portion (49) towards a free endand the second arm (54) has a curved portion (49) mirroring the curvedportion of the first arm (53), the curved portion of the second armhaving an intermediate notch (55), extending inwardly, and facing thefirst arm (53), the intermediate notch providing a supporting surfacefor the single glass container (12).